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Under-sampling is worse than over-sampling.Depending on the result, a message will suggest how the situation might be improved, i.e.Pleasing images can be made using less than optimum equipment. If the result suggests your existing telescope / camera combination is less than ideal please don’t shoot the messenger. The calculator uses maths to determine its result, it is not influenced by brand or sales spiel.The scale changes according to the ‘seeing’ conditions entered. Over 2” is under-sampling and under 0.67" is over-sampling. We are assuming OK seeing is between 2-4” FWHM and a resolution between 0.67” and 2” per pixel is the sweet spot.Simply enter the telescope's focal length, the camera's pixel size and your sky's seeing conditions to determine if they are a good match :-) When using our calculator you you don’t need to understand the theory or the maths. In summary, we are using Nyquist as a starting point, with a slight tweak, because we are typically sampling very small, circular, stars. Our calculator, at typical seeing of 2-4”, uses the Nyquist formula of 1/2 and the 1/3 to stop stars becoming square so the optimal range is between 0.67” and 2”.
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It is better then to image with a resolution 1/3 of the analog signal, doing this will ensure a star will always fall on multiple pixels so remain circular. Using typical seeing at 4” FWHM, Nyquist’s formula would suggest each pixel has 2” resolution which would mean a star could fall on just one pixel, or it might illuminate a 2x2 array, so be captured as a square. There is some debate around using this for modern CCD sensors because they use square pixels, and we want to image round stars. So, if OK seeing is between 2-4” FWHM then the sampling rate, according to Nyquist, should be 1-2”. Nyquist’s formula suggests the sampling rate should be double the frequency of the analog signal. In the 1920s Harold Nyquist developed a theorem for digital sampling of analog signals. In affect, over-sampling reduces field of view. Over-sampled images look rather nice because the stars are round with smooth edges but if you have more pixels than are necessary why not use a reducer to reduce the telescope’s effective focal length, which makes the image brighter and enables you to fit more sky on your sensor.
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For a smoother more natural look more pixels are required, but not too many because if you use more pixels than are necessary to achieve round stars the image is 'over-sampled’. Too few and the image will be 'under-sampled’, the stars will appear blocky and angular'. Short focal length telescopes and ideal seeing conditions provide the smallest stars, longer focal lengths and less favourable skies produce larger stars.įor a star to retain it's round shape when viewed on your screen or photograph it’s diameter must cover a sufficient number of pixels. Assuming high quality optics, the diameter of the point of light is determined by the telescope’s focal length (longer focal lengths result in larger star diameters) and the sky's ‘seeing’ conditions (atmospheric dispersion spreads the point of light, making it larger). In case of smallest image details and large magnifications please use macro-lenses which are specially designed for these applications.įurther details on optical calculations can be found in chapter Optical basics.A telescope focuses a star as a round point of light. Especially in case of very small working distances of several centimetres, the calculated values are no longer realistic. The calculated working distances refer to the optic centre of the lens housing. By means of additional spacers, however, the lens distance can be reduced ("see calculation of close-up rings"). In case of F-mount lenses and other lenses for larger image circle diameters, the minimum lens distances are often considerably larger. Hinweis: Zur einfachen Berechnung bitte einen Wert in der Dropdownbox selektieren! Eingabe eigener Werte durch Auswahl von "User def." in DropDown-Liste!Ĭalculating the working distance using object size and opening angleĪttention: Calculated working distances below 150 to 300 millimetres cannot be focused using normal C-mount lenses. Send your calculation with your own email program (MailTo-link).Īrbeitsabstand: mit Pixelgröße Sensor, Brennweite und Bauteilgröße rechnen We respect your privacy: We do not store any inputs, results or recipients. Length/ size of inspected object in mm (field of view FOV): Note: Even when using the drop-down lists own values can be entered. Using object size& opening angle Calculating the working distance using focal length, object and sensor size